Patent Grant
10882362
This invention relates generally sipe-molding members and tire treads formed there from, and more specifically, sipe-molding members having stiffeners and tire treads formed there from.
Sipes (also referred to as “lamelles”) are commonly formed using molding elements, which is referred to herein as “sipe-molding members”), where a thin member is used to form a sipe during molding operations. A sipe is a very narrow or thin void or slit, such that, during tire operation, opposing sides of the sipe contact or abutting one another. A sipe is distinguishable from a void, such as a lateral or longitudinal groove, whereby a void is sized such that during tire operation, opposing sides of the void remain spaced apart and do not contact one another. By doing so, a void is able to accept water, mud, snow, or any other material for the purpose of facilitating traction between the tread and an intended tire operating surface, such as a road surface.
It is known for metal products to experience unintentional deformation during forming operations, such as metallic laser sintering, for example. Deformation can occur due to the imbalances in heating and cooling. Accordingly, the resulting product can differ dimensionally from the original product design. For example, with regard to sipe-molding elements, this deformation not only can result in a dimensionally imperfect sipe-molding member, it can result in a dimensionally imperfect sipe in a tire tread, which in turn can impact tire performance. Techniques are known to assist in the reduction of deformation, but these techniques either require substitution of different material or altering process parameters such as power or speed. Accordingly, there is a need to provide a manner for reducing deformation during product forming operations for any desired material, such for any powder employed during laser sintering (that is, regardless of the powder employed), and without altering process parameters of the operation.
Particular embodiments of the invention include sipe-molding members comprising a sipe-forming portion and a plurality of stiffening members spaced along the sipe-forming portion. The sipe-forming member has a length extending in a lengthwise direction of the sipe-molding member, a height configured to extend into a depth of a molding cavity, and a thickness extending perpendicular to both the length and height. The sipe-molding member is configured to form a sipe having a thickness commensurate with the thickness of the sipe-forming portion, a length formed by at least a portion of the length of the sipe-forming portion, and a depth formed by at least a portion of the height of the sipe-forming portion. Each of the plurality of stiffening members extend outwardly from the thickness of the sipe-forming element.
Further embodiments of the invention include method for reducing deformation of a sipe-molding member arising during manufacturing operations. Particular embodiments of such methods include a step of forming a sipe-molding member configured to form a sipe in a tire tread. In particular embodiments, the sipe-molding member comprises the sipe-molding member recited above.
Yet further embodiments of the invention methods of forming a molded tire tread. In particular embodiments, such methods include a step of providing a sipe-molding member configured to form a sipe in a tire tread, such as the sipe-molding member described above. A further step includes arranging the sipe-molding member within a mold and molding at least a tire tread, the tire tread including a sipe formed by the sipe-molding member.
The foregoing and other objects, features, and advantages of the invention will be apparent from the following more detailed descriptions of particular embodiments of the invention, as illustrated in the accompanying drawings wherein like reference numbers represent like parts of the invention.
Embodiments of the invention comprise a sipe-molding member including a plurality of stiffening members to resist deformation of the sipe-molding member during sipe-molding member formation (manufacturing) operations, to thereby preserve and maintain the dimensional integrity of the sipe-molding member and its design. Accordingly, particular embodiments of the invention include methods for reducing deformation of a sipe-molding member arising during manufacturing of the sipe-molding member, where such methods comprise forming the sipe-molding member with a plurality of stiffeners as discussed herein. Additional embodiments include methods of forming a sipe-molding member and methods of forming a tire tread or tire having one or more sipes each formed by a sipe-molding member.
In particular embodiments, a sipe-forming element includes a sipe-forming portion having a length extending in a lengthwise direction of the sipe-molding member, a height configured to extend into a depth of a molding cavity, and a thickness extending perpendicular to both the length and height. The sipe-molding member is configured to form a sipe having a thickness commensurate with the thickness of the sipe-forming portion, a length formed by at least a portion of the length of the sipe-forming portion, and a depth formed by at least a portion of the height of the sipe-forming portion. As mentioned above, a sipe is a very narrow or thin void or slit, such that, during tire operation, opposing sides of the sipe contact or abutting one another. A void, such as a lateral or longitudinal groove, is sized such that during tire operation, opposing sides of the void remain spaced apart and do not contact one another. By doing so, a void is able to accept water, mud, snow, or any other material for the purpose of facilitating traction between the tread and an intended tire operating surface, such as a road surface.
The thickness of the sipe-forming portion extends in a direction transverse to both the height and length of the sipe-forming portion. The thickness may be constant or variable. It is appreciated that the length and/or the height of the sipe-forming portion may extend along any linear or non-linear path, which may be arcuate or undulating, for example. “Undulating” connotes that the path alternates between multiple changes in direction resulting in a plurality of peaks and valleys, for example. In other words, an undulating path zigs and zags back and forth multiple instances to provide two or more peaks or valleys (that is, apexes and troughs). Exemplary undulating paths include a sinusoidal, saw-tooth, or square-wave path. Therefore, it is contemplated that the non-linear path may be curvilinear or comprise a plurality of linear segments, or any combination thereof.
The sipe-forming element further includes a plurality of stiffening members spaced along the sipe-forming portion, where each of the plurality of stiffening members extend outwardly from the thickness of the sipe-forming element. In being spaced along the sipe-forming portion, the plurality of stiffening members (also referred to herein as “stiffeners”) may be spaced apart on any one or both sides of the sipe-forming portion thickness, in any direction, such as in a direction of the sipe-forming portion height and/or length (meaning in any such direction or combination of directions, or in both directions). For example, an array of stiffeners maybe arranged to extend in the direction of the sipe-forming portion height or length, or an array in each such direction. It can be said that in extending outwardly, a stiffener member extends outwardly in a direction of the sipe-forming portion thickness, thereby increasing the local thickness of the sipe-forming portion. By providing stiffening members spaced apart along the length and/or height of the sipe-forming portion, the sipe-forming portion becomes a sipe-forming portion having an increased bending modulus to better resist deformation of the sipe-molding member. Stiffeners also provide a sipe-molding member having an improved mass balance, which provides a more balanced or more uniform arrangement of stresses along the sipe-molding member during heating and cooling cycles to thereby reduce or even eliminate deformation of the sipe-molding member.
In particular embodiments, a stiffener has a height extending in a direction of the sipe-forming portion height. In doing so, the stiffener height can either: (1) extend entirely (that is, completely) in a direction of the sipe-forming portion height defining the sipe-forming portion height, which in other words extends in a direction perpendicular to the sipe-forming portion length or (2) extend partially in the direction of the height, such that when parsing the direction in which the stiffener height extends into two or more vector components, one of the vector components extends in a direction of the sipe-forming portion height defining the sipe-forming portion height. It is appreciated that any stiffener may be arranged to extend along any height of the sipe-forming portion. For example, a height of a stiffener may extend the entire height or any partial height of the sipe-forming portion height. Accordingly, in particular embodiments, each of the plurality of stiffeners extending outwardly from the void-forming portion in a direction of the sipe-forming portion height to a terminal end located at or below the terminal end of the sipe-forming portion. It is appreciated that, in particular embodiments, a mold-attachment portion extends from the terminal end of the sipe-forming portion, which is discussed further herein.
In particular embodiments, a stiffener has a length extending in a direction of the sipe-forming portion length. In doing so, the stiffener length can either: (1) extend entirely (that is, completely) in a direction of the sipe-forming portion length defining the sipe-forming portion length, which in other words extends in a direction perpendicular to the sipe-forming portion height or (2) extend partially in the direction of the length, such that when parsing the direction in which the stiffener length extends into two or more vector components, one of the vector components extends in a direction of the sipe-forming portion length defining the sipe-forming portion length. It is appreciated that any stiffener may be arranged to extend along any length of the sipe-forming portion. For example, a length of a stiffener may extend the entire length or any partial length of the sipe-forming portion length.
It is also appreciated that the stiffener may comprise any desired shape, externally and in cross-section, such as along a plane extending perpendicular to the length of the stiffener. For example, the external shape of a stiffener may be a partial cone, cylinder, or disk, or may comprise a rectangle or square. It is also appreciated that the stiffener may be hollow or solid.
In particular embodiments, the sipe-molding member further includes a void-forming portion having a length extending in a lengthwise direction of the sipe-molding member, or in any other direction of the sipe-molding member or any direction relative the sipe-forming portion. In such embodiments, the height of the sipe-forming portion extends outwardly from the void-forming portion. It is appreciated that the void-forming portion may form any desired void, such as a lateral or longitudinal groove, for example. It is also appreciated that the void-forming portion may be configured to form a void at any location in the tread thickness. For example, in certain embodiments, the void-forming portion is a submerged-forming portion configured to form a void submerged within the tread thickness from a ground-engaging side of the tread. Sipe-molding members having a submerged void-forming portion form what is known within the industry as a tear-drop sipe, where the sipe height extends outwardly toward a ground-engaging side of the tread from a submerged void. Of course, it is understood that the void-forming portion may be arranged to form a void along the ground-engaging side of the tread, such that the void is not submerged and the sipe formed by the sipe-forming portion is instead submerged within the tread thickness below the ground-engaging side of the tread, where the sipe extends into the tread thickness from the void. When submerged, the void or sipe is offset below the ground-engaging side of the tread.
It is appreciated that any sipe or void may have a length extending in any direction transverse to the tread thickness, such as in a direction of the tread length and/or width. For example, the sipe or groove may be a longitudinal or lateral sipe or groove. Longitudinal grooves or sipes generally extend in a direction of the tread length, which may extend circumferentially around the tire. It is also contemplated that a longitudinal groove or sipe may extend at an angle biased to a circumferential direction of the tire. Lateral grooves or sipes generally extend in a direction of the tread width, where the lateral groove or sipe generally extends in a direction perpendicular to a longitudinal centerline of the tread (which extends in a direction of the tread length) or at an angle biased to the longitudinal centerline. It is appreciated that the length of any void or sipe may extend along any linear or non-linear path as desired, where a non-linear path is more fully described herein. Moreover, unless otherwise specified herein, any groove discussed herein may comprise a lateral or longitudinal groove and any sipe may comprise a lateral or longitudinal sipe. Accordingly, unless otherwise specified, a void-forming portion may be a longitudinal or lateral void-forming portion, which is configured to form a longitudinal or lateral groove, respectively. Likewise, unless otherwise specified, a sipe-forming portion may be a longitudinal or lateral sipe-forming portion, which is configured to form a longitudinal or lateral sipe, respectively.
It is appreciated that a stiffener may be spaced-apart from the submerged void-forming portion; however, in certain instances, the plurality of stiffening members are spaced apart along the length of the submerged void-forming portion, where each of the plurality of stiffening members are arranged to extend from and between each of the submerged void-forming portion and the sipe-forming portion.
In particular embodiments, where the sipe-forming portion extends along an undulating, non-linear path in a direction of the sipe-forming portion height, each of the plurality of stiffeners extends between undulations or from one undulation to another undulation of the sipe-forming portion. In doing so, the plurality of stiffeners may be aligned in a direction of the sipe-forming portion height between adjacent undulations, or may be staggered in a direction of the sipe-forming portion length between adjacent undulations. In other embodiments, where the sipe-forming portion extends along an undulating, non-linear path in a direction of the sipe-forming portion length, each of the plurality of stiffeners extends between undulations (that is, a pair of undulating portions) of the sipe-forming portion. In doing so, the plurality of stiffeners may be aligned in a direction of the sipe-forming portion length between adjacent undulations, or may be staggered in a direction of the sipe-forming portion height between adjacent undulations.
In particular embodiments, where a plurality of stiffeners are employed, one or more of the plurality of stiffeners are arranged along each opposing side of the sipe-forming portion, that is, in other words, on opposing sides of the sipe-forming portion thickness. Still, it is appreciated that the plurality of stiffeners may only be arranged on one side of the sipe-forming portion. In instances when stiffeners are arranged on both sides of the sipe-forming portion, the stiffeners may be arranged in any relative side-to-side relationship. In one example, the one or more of the plurality of stiffeners arranged along a first of the opposing sides of the sipe-forming portion thickness are arranged opposite the one or more of the plurality of stiffeners arranged along a second of the opposing sides of the sipe-forming portion thickness. In another example, one or more of the plurality of stiffeners arranged along a first of the opposing sides of the sipe-forming portion thickness are arranged in a staggered relationship along the length of the sipe-forming portion relative to the one or more of the plurality of stiffeners arranged along a second of the opposing sides of the sipe-forming portion thickness.
As noted above, particular embodiments of the invention include methods for reducing deformation of a sipe-molding member arising during manufacturing of the sipe-molding member, where such methods comprise forming the sipe-molding member with a plurality of stiffeners in accordance with any embodiment contemplated herein. It is appreciated that in any embodiment described herein, the sipe-molding member may be formed by any known process. For example, in particular embodiments, the sipe-molding member is a laser sintered product, formed by any known laser sintering process, such as direct or selective laser sintering. By further example, the sipe-molding member may be formed by other 3-dimensional printing processes, molding, or casting. It is also appreciated that the plurality of stiffeners may be added to a pre-existing sipe-molding member, using any know manner for attaching the stiffeners, such as by using adhesive(s), welding, or even fasteners. It is understood that the sipe-molding member may be formed of any known material or composition. Exemplary compositions include any metal or metal composition.
Additional embodiments of the invention include methods of forming a tire tread or tire having one or more sipes each formed by a sipe-molding member. After forming and providing the sipe-molding member, the sipe-molding member is arranged within a mold, the mold having a molding cavity configured to mold at least a tire tread, where the sipe-forming portion of the sipe-molding member is arranged in the molding cavity. To facilitate installation of the sipe-molding member within the mold, in particular embodiments, the sipe-molding member includes a mold-attachment portion, which may comprise any structure or mechanism known to one of ordinary skill in the art. The molding cavity is configured to mold a tire tread, such as when forming a tread for later application to a tire carcass in retreading operations, or a tire that includes a tire tread. In any event, the molding cavity is defined at least in part by an outermost molding surface configured to form a ground-engaging side or surface of the tire tread. The outermost molding surface can also be referred to as the ground-engaging molding surface or portion of the mold or molding cavity. The outermost molding surface is arranged along an outer cavity side, which is generally annular or circumferential in shape. Therefore, when relating any feature of the mold or tire tread to the outermost molding surface, the same relation can be made or drawn relative to the outer cavity side by substituting the outer cavity side for the outermost molding surface. In instances where the sipe-molding member includes a void-forming element, each of the sipe-forming portion and the void-forming portion of the sipe-molding member are arranged in the molding cavity. It is appreciated that the sipe-molding members may be attached or affixed in a mold using any manner known to one of ordinary skill. For example, in particular embodiments, the sipe-molding member includes a mold-attachment portion, which is used to attach to the element to the mold.
Additional embodiments of the method include steps of arranging an uncured tire tread within the mold and curing the tire tread within the mold. During the molding process, the tread is cured, as the tread is generally formed of a curable elastomeric material, such as natural or synthetic rubber or any other polymeric material. These steps contemplate that the mold may be a tire tread mold or a tire mold as discussed further above.
Particular embodiments of the sipe-molding members and methods discussed above will now be described in further detail below in association with the figures filed herewith providing exemplary embodiments of the sipe-molding members and the performance of the methods.
With reference to
In
With reference to another exemplary embodiment in
In the exemplary embodiment shown in
As noted above, the stiffeners may be arranged in any relation on opposing sides of the sipe-forming portion. For example, in the embodiment shown in
As also noted above, it is understood that stiffeners may comprise any shape. For example, with reference to the embodiment shown in
The terms “comprising,” “including,” and “having,” as used in the claims and specification herein, shall be considered as indicating an open group that may include other elements not specified. The terms “a,” “an,” and the singular forms of words shall be taken to include the plural form of the same words, such that the terms mean that one or more of something is provided. The terms “at least one” and “one or more” are used interchangeably. The term “single” shall be used to indicate that one and only one of something is intended. Similarly, other specific integer values, such as “two,” are used when a specific number of things is intended. The terms “preferably,” “preferred,” “prefer,” “optionally,” “may,” and similar terms are used to indicate that an item, condition or step being referred to is an optional (i.e., not required) feature of the invention. Ranges that are described as being “between a and b” are inclusive of the values for “a” and “b” unless otherwise specified.
While this invention has been described with reference to particular embodiments thereof, it shall be understood that such description is by way of illustration only and should not be construed as limiting the scope of the claimed invention. Accordingly, the scope and content of the invention are to be defined only by the terms of the following claims. Furthermore, it is understood that the features of any specific embodiment discussed herein may be combined with one or more features of any one or more embodiments otherwise discussed or contemplated herein unless otherwise stated.
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